Procedure for filling alcoholic beverages, in particular wine, into stand-up type pouches made from polylaminate material

ABSTRACT

A procedure for filling alcoholic beverages, in particular wine, into stand-up type containers made from polylaminate material comprises the following operational steps: a) preparing a stand-up type container; b) mechanically opening the upper part of the container ( 21 ) to form a filling space; c) injecting an inert gas in the filling space with the aim of reducing the presence of oxygen in the space; d) introducing a predetermined quantity of an alcoholic beverage, in particular wine, inside the space; e) closing without sealing the open edges of the container ( 21 ); f) sealing the upper part of the container ( 21 ) to form a hermetically closed container and containing an alcoholic beverage, in particular wine. The polylaminate material used comprises a cellulose layer having a basic weight of not less than 150 g/m2; the mechanical opening comprises the mechanical opening from the inside of the mouth of the container ( 21 ) and the deep injection into the container of a high pressure jet of air; step f) is performed inside a sealing station ( 38 ) in which a first sealing unit ( 55 ) performs a hermetic sealing operation fulling sealing a shaped strip inside the upper portion of the container ( 21 ).

TECHNICAL FIELD

This invention relates to an industrial procedure for filling alcoholic beverages, in particular wine, into stand-up type pouches made from polylaminate material. This invention also relates to a filling machine designed to perform the procedure.

The machine according to the invention comprises certain operating stations which are able to perform various advanced functions during the filling steps, at the end of which there is a final product of high quality, which is especially necessary in the presence of high quality wines.

This invention can be applied in the field of machines for filling beverages such as wines or the like in containers and in particular in paper-based polylaminate containers.

BACKGROUND ART

It is known that machines currently exist on the market allowing automation of the operations for packaging a wide range of food products in a wide range of containers made from a wide range of materials.

One of the containers most commonly used for beverages which, in addition to glass, gives the best results from the point of view of conservation is the cellulose-based polylaminate container; this is a packaging system for foodstuffs which is widely used throughout the world for the conservation of a wide variety of beverages and liquid foodstuffs such as milk and fruit juices.

The polylaminate packaging is a container which, depending on the commercial life-span of the product, can consist of paper, plastic and aluminium or paper and plastic. The first type allows a long conservation of the foods, of between six and twenty four months, at ambient temperature, whilst the container made of paper and plastic is used for the short-term conservation of fresh foods at low temperatures.

The cellulose-based polylaminate containers are currently made using machines for the production of beverage containers, also for single use, where the machines comprise means for making containers made from polylaminate material, starting from a sheet of polylaminate material made of paper, generally comprising two main folds facing each other and sealed at the edges, a bottom fold joined with the main folds and withdrawn between the two main folds along a median line and an opening positioned between the two main folds in a counter-opposed position with respect to the base fold.

These containers are generally defined as “stand-up” and a type of these containers is described in patent document US 2012/0008884 A1, which also describes a system for filling liquids inside the containers.

Patent document US 2011/167763 A1 also describes a system which allows the filling and closing by heat sealing, of stand-up type containers.

These machines comprise filling means designed to introduce a predetermined quantity of liquid in the container, closing means designed for closing the opening after introduction of the liquid, as well as means allowing a predetermined quantity of inert gas to be injected into the container, after introducing the liquid.

It has been found that these machines lack means which allow the perfect shape of the finished container to be obtained and also means which allow the environment for injection of the liquid and the subsequent environment for closing the container to be kept perfectly aseptic.

Due to these drawbacks, the prior art machines do not allow finished containers with a high quality to be obtained and consequently the beverages contained therein are easily perishable especially if they are alcoholic beverages, in particular wine, which is notoriously much more subject to oxidation phenomena and deterioration, compared with other beverages.

Moreover, in the particular case of containers filled with alcoholic beverages, in particular but not exclusively wine, the polylaminate materials conventionally used in the industry for making containers for food products are not adequate to constitute a container which is at the same time robust, sterile and perfectly sealed from the outside environment. In the opinion of the Applicant, there are no systems which are able to produce robust, sterile and perfectly sealed containers filled with alcoholic beverages, in particular wine, on a large scale.

DESCRIPTION OF THE INVENTION

The present invention provides a procedure and a machine which makes it possible to eliminate or at least reduce the drawbacks described above.

This is achieved by means of a procedure for filling alcoholic beverages, in particular wine, into stand-up type containers made from polylaminate material having the characteristics described in the main claim.

The dependent claims describe advantageous embodiments of the invention.

The main advantages of this solution, in addition to those deriving from the construction simplicity, concern the fact that the machine for implementing the procedure according to the invention allows a high standard of quality of the containers finished and ready for use to be obtained, improving the constancy of the production which is made much more reliable compared with that possible with the known solutions.

The machine for implementing the procedure according to the invention substantially comprises means which allow the making in series of containers which can be filled with alcoholic beverages, in particular wine, starting from a continuous sheet of cellulose-based polylaminate material having an extremely robust laminar structure; it not being possible to use this material according to the prior art procedures and with the prior art machines.

The machine for implementing the procedure according to the invention uses a plurality of workstations, including a station for pre-shaping the container, a station for dosing gas in the presence of ultraviolet ray lamps, a station for dosing the alcoholic beverage, in particular wine, a further station for dosing inert gas positioned immediately upstream of a closing station in which the container is hermetically closed by heat or ultrasound sealing.

DESCRIPTION OF THE DRAWINGS

Other features and advantages of the invention will become clear on reading the description given below of one embodiment, provided as a non-binding example, with the help of the accompanying drawings, in which:

FIG. 1 illustrates a schematic side view showing the layout of the different workstations of an automatic packaging machine of containers made from polylaminate material filled with an alcoholic beverage, in particular wine;

FIG. 2 illustrates a schematic perspective view of certain operational steps of the machine for implementing the procedure according to the invention;

FIG. 3 illustrates a schematic view from below of a portion of the machine for implementing the procedure according to the invention wherein a filled container is moved through a tunnel for bringing together the open flaps of the container;

FIG. 4 illustrates a schematic perspective view of the structure of the tunnel of FIG. 3;

FIG. 5 illustrates a schematic front view of the outlet of the tunnel of FIG. 3;

FIG. 6 illustrates a schematic side view of the upper portion of a container made according to the invention, with particular reference to the first sealing of the upper portion;

FIG. 7 schematically illustrates the first sealing operation of the upper portion of the container as shown in FIG. 6;

FIG. 8 illustrates a schematic side view of the upper portion of a container made according to the invention, with particular reference to the second sealing of the upper portion;

FIG. 9 schematically illustrates the second sealing operation of the upper portion of the container as shown in FIG. 8; and

FIGS. 10A, 10B, 10C and 10D illustrate schematic side views in which the different sealings made on the container are respectively shown according to the procedure of the invention.

DESCRIPTION OF ONE EMBODIMENT OF THE INVENTION

FIG. 1 shows a machine for implementing the procedure according to the invention designed for packaging and filling containers made from polylaminate material, indicated overall with the number 10.

The machine for implementing the procedure according to the invention generally comprises a machine for packaging containers made of polylaminate material, where the containers are initially made in known fashion starting from a continuous sheet of cellulose-based polylaminate material which is unwound from a reel 11, which passes between rollers positioned at an initial station 12 in which the sheet is folded into two main flaps alongside each other. A similar machine, with a circular structure, is described in the above-mentioned patent document US 2012/0008884 A1.

A first important feature of the invention is the type of polylaminate material which is used for implementing the procedure according to the invention. In effect, studies, research and experiments carried out by the Applicant have shown that the conventional polylaminate materials used for producing containers, also for single use, for long-life food products are not suitable for the production of containers for alcoholic beverages, in particular wine. It is has been found that the conventional containers are equipped with a layer of paper with a low basic weight, in particular less than 100 g/m2, which is not able to adequately withstand the sophisticated sealing procedures to which the containers must be subjected after filling with the aim of guaranteeing the perfect seal, sterility and substantial absence of oxygen inside the container.

These production procedures are supported solely by cellulose-based polylaminate materials wherein the cellulose layer comprises cardboard with a basic weight of between 150 and 250 g/m2. Excellent results can be obtained using a cellulose-based polylaminate material wherein the cellulose layer comprises cardboard with a basic weight of 180 g/m2.

By way of a non-binding example, a sheet made of polylaminate material which can be used for implementing the procedure according to the invention has the following structure, starting from the outer side towards the inner side of the finished container:

low-density polyethylene (LDPE) 15 g/m2;

pure cellulose cardboard 180 g/m2;

low-density polyethylene (LDPE) 20 g/m2;

aluminium foil—6.3 micron 17 g/m2;

ethylene-methacrylic acid copolymer 10 g/m2;

low-density polyethylene (LDPE) 10 g/m2;

linear low-density polyethylene (LLDPE film) 25 micron 23 g/m2.

The various layers mentioned above can vary in composition and weight. However, it appears essential that the basic weight of the cardboard is never less than that shown above.

Conventionally, the sheet folded previously is intercepted inside a second workstation 13 by a component which pushes it at its lower folded edge, in such a way as to form a bottom fold folded inside and upwards.

Inside the third workstation 14 of the machine the shaped container, which is still in the form of a continuous sheet which in a vertical section is now substantially “W”-shaped, is subjected to a first heat-sealing process of two counter-opposing vertical edges 40, 41 (see FIGS. 10A to 10D), using conventional heat-sealing devices, which operate cyclically during the continuous feed of the sheet.

The sheet pre-shaped and with the vertical edges 40, heat sealed is then subjected to operations for separating the various containers by cutting with conventional counter-opposing blades, creating a series of substantially rectangular, closed containers.

The separated containers, each of which has a base with a “W”-shaped vertical cross-section and two vertical heat-sealed sides, are now close to a plurality of further workstations for filling and closing the individual containers.

It should be noted that, due to the selection of the polylaminate material having a cellulose layer with a basic weight of not less than 160 g/m2, the container which is formed possesses a rigidity which is much greater than that of conventional containers of the stand-up type used for food products. Experiments carried out by the Applicant have shown that the means conventionally used for opening containers with the aim of being able to fill them, the means comprising a mechanism with suckers acting on the counter-opposing flaps of the container and a jet of air acting in the container (see, for example, patent document US 2012/0008884 A1), are not absolutely sufficient to guarantee the complete opening of the containers used in the procedure according to the invention, due to the greater rigidity of the latter.

The machine designed to implement the procedure according to the invention therefore has, as well as the conventional system with suckers and a jet of air to perform a preliminary opening of the containers, the following additional workstations, the operation of which is illustrated in FIGS. 1 and 2:

-   1. station 15 wherein the mouth of the opening 21 is mechanically     opened by inserting in the mouth of each container a truncated     cone-shaped tool with an elliptical cross section, that is hollow     inside, as well as sending a high pressure jet of air inside the     truncated cone-shaped tool with the aim of further widening the base     of the container; -   2. station 16 for injecting sterilising gas, in particular nitrogen,     inside each container 21. It should be noted that the prior art     systems, for example that described in patent document US     2012/0008884 A1, have a single nozzle which blows an inert gas, for     example nitrogen, inside the container with the aim of reducing the     presence of oxygen inside the container 21. In the case of the     procedure and the machine according to the invention, which     describes the filling of containers with alcoholic beverages, in     particular wine, the elimination of the oxygen inside the container     must be as accurate as possible with the aim of avoiding the     formation of oxidation reactions of the product inside the     containers once they are closed. As shown in FIG. 2, the station 16     comprises an elongated cylindrical nozzle 25 which is inserted to     the bottom inside each container 21 and emits a high pressure jet of     inert gas, in particular nitrogen, at the base of the container.     This allows a further final opening of the base of the container,     and guarantees the almost total elimination of the oxygen present     inside the container. Lastly, with the aim of guaranteeing the     sterility of the procedure in progress, the nozzle 25 during its     movement is subjected to the action of a pair of UV lamps 26 which     guarantee the constant disinfection; -   3. station 17 of the conventional type, for filling the containers     21, in which a predetermined quantity of the alcoholic beverage, in     particular wine, is injected inside each container, in which there     is a modified atmosphere, using a vertically movable nozzle 28; -   4. station 18 for pre-closing the containers 21, at which a pair of     movable bars 29 gently move together the upper flaps of each filled     container 21, and where there is a nozzle 31 comprising a flat     element that is hollow inside, which is movable in the same     direction of movement as the containers, which sprays an inert gas     in the closing area of the container, with the aim of avoiding the     presence of oxygen in the closing area; -   5. station 19 for sterilising the closing area, in which the upper     portion of each container 21 is inserted inside a sterilising tunnel     35 having a structure with the shape of an elongated tunnel inside     of which there is a fork 36 that definitively moves together the     upper edges of the container 21 moved forward. The tunnel 35 is also     equipped with a series of holes (not shown in the Figures) through     which an inert gas, for example nitrogen, is sprayed in the sealing     area with the aim of avoiding the presence of oxygen; -   6. pre-sealing station 20, positioned at the outlet of the tunnel     35, and in which the upper part of the container 21 passes through a     pair of pre-heating rollers 30 which definitively close the     container, preparing it for the entrance into the sealing stations.

In each of the workstations, each container 21 moves forward pushed by gripping means of the conventional type forming part of automatic filling machines for liquid food products.

In the conventional systems for filling containers of the stand-up type there are generally one or two sealing stations, in particular heat sealing, which are typically identical, the aim of the second sealing operation being solely that of strengthening the effects of the first sealing. In the case of the procedure according to the invention, which uses a cellulose-based polylaminate material wherein the cellulose layer has a basic weight of less than 150 g/m2, the conventional sealing system is not sufficient to guarantee the total seal of the container filled with an alcoholic beverage, in particular wine.

According to the invention, the machine 10 comprises a sealing station 38 inside of which there are two sealing systems which perform different operations. As shown in FIGS. 6, 7 and 10B, the first sealing system comprises a sealing unit 55 with counter-opposing plates 56, 56′ rotatable about a common pin 57. Each plate 56, 56′ is equipped with a shaped sealing area 58, 58′ raised relative to the profile of the plate, which is able to perform high temperature sealing of a predetermined shaped area 60 of the container 21. The high temperature sealing (at about 250° C.) allows any liquid residue present in the sealing area to be eliminated, thereby avoiding the formation of possible bubbles which can result in an imperfect seal of the container 21.

The sealing, which acts on a limited surface, can, according to the invention, be performed by heat as described above; however, the sealing can also be performed by ultrasound or by electro-induction.

As shown in FIGS. 8, 9 and 10C, the second sealing system comprises a sealing unit 65 having a pair of counter-opposing plates 66, 66′, which are movable linearly in the same direction and in opposite directions. The action of the plates 66, 66′, which operate at a temperature lower than that of the plates 56, 56′ of the first sealing system, allow the flaps 67 of the upper portion of the container 21 to be sealed.

As shown in FIG. 10D, the final closed container has, in effect, three different types of sealings; more specifically, the initial sealing areas 40, 41 of the vertical edges of the container, the high temperature sealing area 60 of the upper shaped edge of the container, and the low temperature sealing area 67 of the upper flaps of the container.

Lastly, the container reaches a final cutting station 43, wherein a pair of side portions of the upper part of the container 21 are cut and separated from the container, which adopts the shape of a bottle.

The container is then sent to further steps for storage.

As can be seen, this succession of steps ensures that the filling of the liquid foodstuff, in particular wine, takes place under conditions which are absolutely favourable for keeping it inside the container, creating the ideal conditions for its perfect conservation in this particular type of container created specifically for single-use consumption.

The invention as described above refers to a preferred embodiment. It is nevertheless clear that the invention is susceptible to numerous variations which lie within the scope of its disclosure, in the framework of technical equivalents. 

1.-11. (canceled)
 12. A procedure for filling alcoholic beverages, in particular wine, into stand-up type containers made from polylaminate material comprising the following operational steps: a) preparing a stand-up type container starting from a continuous sheet in the form of a reel of polylaminate material which is performed inside a machine that subsequently performs a first operation for folding the sheet to form two main folds alongside each other, a second folding operation during which a base fold folded inwards is formed at the folded edge, and a third operation for sealing two counter-opposing vertical edges of the container, in such a way as to form a container closed on three sides and which can be opened on the upper part; b) mechanically opening the upper part of the container to form a filling space using a system of suckers which from the outside separate the counter-opposing flaps of the container and a jet of air sent at the opening area; c) injecting an inert gas n the filling space with the aim of reducing the presence of oxygen in the space; d) introducing a predetermined quantity of liquid foodstuff inside the space; e) closing without sealing the open edges of the container under the action of an inert gas with the aim of reducing the presence of oxygen in the closing area; f) sealing the upper part of the container to form a hermetically closed container and containing a liquid foodstuff; and wherein: the polylaminate material used comprises a cellulose layer having a basic weight of not less than 150 g/m2; the mechanical opening under step b) also comprises the mechanical opening from the inside of the mouth of the container and the deep injection into the container of a high pressure jet of air; step c) is performed by inserting inside the container a nozzle which injects a high pressure inert gas, at the base of the container, causing the complete unfolding of the base of the container, as well as the moving away of the oxygen present inside the space; step e) is performed by moving the container filled with an alcoholic beverage, wine in particular, inside a structure comprising a sterilizing tunnel in which the open edges of the container are placed alongside each other and an inert gas is emitted inside the tunnel with the aim of keeping the edges of the container are placed alongside each other free from the presence of oxygen; and step f) is performed inside a sealing station in which a first sealing unit performs a hermetic sealing operation fulling sealing a shaped strip inside the upper portion of the container and a second sealing unit seals the remaining upper portion of the container not touched by the first sealing.
 13. The procedure according to claim 12, wherein the polylaminate material comprises at least one outer layer made from low-density polyethylene (LDPE), an inner layer made from linear low-density polyethylene (LLDPE), as well as an intermediate layer comprising an aluminum foil.
 14. The procedure according to claim 13, wherein the mechanical opening from the inside of the counter-opposing flaps of the container is performed using a truncated cone-shaped tool with a substantially ellipsoidal base, which is hollow inside, that is inserted in depth between the counter-opposing walls of the container, opening them, and in that a high pressure jet of air is emitted inside the central cavity of the tool with the aim of reaching the base of the container and opening the base of the container.
 15. The procedure according to claim 14, wherein the nozzle for injecting inert gas comprises an elongated cylindrical element movable vertically in such a way as to be able to be inserted in depth inside the container, and in that during the relative movement of the nozzle it is subjected to the action of a pair of counter-opposing ultraviolet light lamps which sterilize nozzle.
 16. The procedure according to claim 15, wherein upstream of the sterilizing tunnel there is a nozzle comprising a flat element that is hollow inside which sprays an inert gas in the closing area of the container with the aim of avoiding the presence of oxygen in the closing area.
 17. The procedure according claim 16, wherein downstream of the sterilizing tunnel there is a pair of pre-sealing rollers which position alongside each other the counter-opposing walls of the upper portion of the container thereby arranging them to be sealed.
 18. The procedure according claim 17, wherein the first sealing unit comprises a pair of counter-opposing plates rotatable about a common pin, each plate being equipped with a shaped, raised sealing area, the combined operation of the plates causing the high temperature sealing of the shaped strip.
 19. The procedure according to claim 18, characterized in that the sealing is performed on the plates at a temperature of greater than 220° C., preferably at about 250° C.
 20. The procedure according to claim 18, wherein in a further work step the upper part of the container filled and sealed is cut in a cutting station with the aim of giving the container the shape of a bottle, the final container thereby having three different types of sealings, more specifically, a pair of side sealings of the vertical edges of the container, a high temperature shaped sealing strip of a portion of the upper area of the container, and a further sealing area of the upper portion of the container.
 21. The procedure according to claim 12, wherein the sealing is performed by the first sealing unit by ultrasound or by electro-induction.
 22. The procedure according to claim 20, wherein the inert gas is nitrogen.
 23. The procedure according to claim 12, wherein the mechanical opening from the inside of the counter-opposing flaps of the container is performed using a truncated cone-shaped tool with a substantially ellipsoidal base, which is hollow inside, that is inserted in depth between the counter-opposing walls of the container, opening them, and in that a high pressure jet of air is emitted inside the central cavity of the tool with the aim of reaching the base of the container and opening the base of the container.
 24. The procedure according to claim 12, wherein the nozzle for injecting inert gas comprises an elongated cylindrical element movable vertically in such a way as to be able to be inserted in depth inside the container, and in that during the relative movement of the nozzle it is subjected to the action of a pair of counter-opposing ultraviolet light lamps which sterilize nozzle.
 25. The procedure according to claim 12, wherein upstream of the sterilizing tunnel there is a nozzle comprising a flat element that is hollow inside which sprays an inert gas in the closing area of the container with the aim of avoiding the presence of oxygen in the closing area.
 26. The procedure according claim 12, wherein downstream of the sterilizing tunnel there is a pair of pre-sealing rollers which position alongside each other the counter-opposing walls of the upper portion of the container thereby arranging them to be sealed.
 27. The procedure according claim 12, wherein the first sealing unit comprises a pair of counter-opposing plates rotatable about a common pin, each plate being equipped with a shaped, raised sealing area, the combined operation of the plates causing the high temperature sealing of the shaped strip.
 28. The procedure according to claim 12, characterized in that the sealing is performed on the plates at a temperature of greater than 220° C., preferably at about 250° C.
 29. The procedure according to claim 12, wherein in a further work step the upper part of the container filled and sealed is cut in a cutting station with the aim of giving the container the shape of a bottle, the final container thereby having three different types of sealings, more specifically, a pair of side sealings of the vertical edges of the container, a high temperature shaped sealing strip of a portion of the upper area of the container, and a further sealing area of the upper portion of the container.
 30. The procedure according to claim 13, wherein the sealing is performed by the first sealing unit by ultrasound or by electro-induction.
 31. The procedure according to claim 20, wherein the inert gas is nitrogen. 